Influence of Cd impurity on the electronic properties of CuAlO2 delafossite: first-principles calculations

Lalić, M.V.; Mestnik-Filho, J.; Carbonari, A. W.; Saxena, R. N.; Moralles, M.

doi:10.1088/0953-8984/14/22/305

Cited by 30 publications

(37 citation statements)

References 22 publications

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“…Several groups theoretically calculated the effects on the electronic behavior of the material due to the presence of various cations in Cu and/or Al sites. Lalić et al [188][189][190] showed that Cd and Zn substitutions on Cu site would produce n-type conductivity in the material, whereas Ni doping in Cu sites would enhance the p-type conductivity of the material. But Cd doping on Al sites would have no effect on the electrical properties of the material.…”

Section: In This Conformation Eight Electrons (Including 2smentioning

confidence: 99%

Reactive SputteredWide-Bandgap p-Type Semiconducting Spinel AB2O4 and Delafossite ABO2 Thin Films for “Transparent Electronics”

Banerjee¹,

Chattopadhyay

2008

Reactive Sputter Deposition

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Reactive sputtering is one of the most widely used techniques for preparing compound thin films (such as oxides, nitrides, carbides, etc.) by sputtering metal targets in an active gas atmosphere (Ar + O 2 /N 2 /CH 4 , etc.) [1][2][3][4]. In this chapter, we have discussed, in details, the formation of spinel and delafossite materials of the form AB 2 O 4 and ABO 2 (A and B may be monovalent, divalent, trivalent, or tetravalent cations, depending on the crystal structure, described later) by reactive sputtering technique. Specially, wide bandgap, ptype semiconducting, and transparent oxide materials with delafossite and spinel structure, having interesting applications in "Transparent Electronics," have been discussed in details. In Sects. 12.2-12.5, a detailed review on the structural, optical, and electrical properties of these p-type transparent conducting oxides (p-TCOs), deposited by reactive sputtering technique, has been presented and the origin of p-type conductivity of these materials has been discussed with considerable attention. Most of the results presented in these sections are reported by various authors working on this field. In Sect. 12.6, synthesis and electro-optical characterization of one of the very important delafossite, p-type semiconducting, and wide-bandgap material, such as CuAlO 2 , produced by our group via reactive sputtering technique, have been discussed in details. Detailed discussions on spinel-and delafossitestructured material can be found in various literatures [5][6][7][8][9][10][11][12][13][14]. Also, detailed reviews on the p-TCO materials have been published by us and others [15][16][17], which cover the syntheses and properties of a range of p-TCO materials reported so far.

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Section: In This Conformation Eight Electrons (Including 2smentioning

confidence: 99%

Reactive SputteredWide-Bandgap p-Type Semiconducting Spinel AB2O4 and Delafossite ABO2 Thin Films for “Transparent Electronics”

Banerjee¹,

Chattopadhyay

2008

Reactive Sputter Deposition

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“…[4] we presented band-structure calculations for CuAlO 2 compound with an isolated Cd impurity substituting either Cu (Cd Y Cu) or Al (Cd Y Al) atom. In both cases Cd changes interatomic distances in its neighborhood.…”

Section: Calculations and Interpretation Of The Resultsmentioning

confidence: 99%

“…The task was too complicated to be done directly, by performing the calculations for all compounds, since all of them except the CuAlO 2 are anti-ferromagnets with complicated alignments of magnetic moments (a fact which is difficult to treat accurately in the theory). Instead, we achieved the goal indirectly, in three consecutive steps: 1) by analyzing results of our previous theoretical study of doped CuAlO 2 compound [4] which exhibits an elevated EFG when Cd substitutes the Cu site, and performing some additional EFG decompositions; 2) by calculating EFGs in group of molecules constructed in a way which simulate the Cd neighborhood in delafossites; 3) by calculating electronic structure and the EFG in Cd-doped CuCrO 2 compound, which exhibits the smaller EFG at Cd occupying the Cu site. All calculations were performed using the full potential linear augmented plane wave (FP-LAPW) method [5], as embodied in WIEN2k computer code [6].…”

Section: Introductionmentioning

confidence: 99%

Correlation between the EFG Values Measured at the Cd Impurity in a Group of Cu-based Delafossites and the Semiconducting Properties of the Latter

Lalić

Mestnik-Filho

2004

Hyperfine Interact

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In this paper we analyze trend of EFG values measured at Cd impurity in a group of semiconducting delafossites with chemical formula CuBO 2 (B = Al, Fe, Cr, Nd). We conclude that this trend reveals one of the most subtle details in electronic spectrum of the compounds: if impurity states are formed within or out of the band gap. In CuAlO 2 and CuFeO 2 the Cd EFG exhibits larger value than in CuCrO 2 and CuNdO 2 , when Cd substitutes the Cu atom. This occurs because in the first two compounds the Cd forms shallow band within the gap, and in the second two compounds does not. When Cd occupies the B position it exhibits almost the same EFG in all delafossites. In this case, Cd does not form its states within the gap in none of the compounds. To arrive to these conclusions we analyzed and calculated various systems (Cd-doped CuAlO 2 and CuCrO 2 compounds, fictitious molecules), using the FP-LAPW method.

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“…This conclusion emerged as a result of series of the first-principles full-potential linear augmented plane wave (FP-LAPW) calculations that we performed for the CuAlO 2 system containing Cd impurities [4], and the Zn or Ni impurities [5] at the Cu position. In this paper we continue to investigate the A site doping effects in the SDOs, but now in their Ag-based branch.…”

Section: Introductionmentioning

confidence: 92%

“…This band is impurity induced, half filled (one electron), and consists mainly of the Cd s and d z 2 , NN O p z and second NN Cu d states. Since its electron density is widely spread over the crystal [4] (Fig. 2b), the electronic structure displays some relevant differences.…”

Section: Cd-doped Compoundsmentioning

confidence: 99%

Electronic structure of the n-type doped AgInO2 and CuAlO2 delafossites: similarities and differences

Lalić¹,

Mestnik-Filho²,

Carbonari³

et al. 2004

Braz. J. Phys.

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We performed the first-principles band-structure calculations for a pure and a Cd-doped AgInO 2 delafossite compound. The results are carefully analyzed and compared with the results obtained for a pure and a Cddoped CuAlO 2 compound, calculated previously by our group. The electronic structures of both systems are found to be similar in many details, being characterized by the same hybridization scheme that occurs at both Cu and Ag positions. Introduction of Cd impurity into the Cu site produces a shallow band within the CuAlO 2 gap, while the Cd presence at the Ag site creates a wide band pinned at the Fermi level in the AgInO 2 spectrum. In both cases, however, the n-type conductivities are predicted.

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Influence of Cd impurity on the electronic properties of CuAlO2 delafossite: first-principles calculations

Cited by 30 publications

References 22 publications

Reactive SputteredWide-Bandgap p-Type Semiconducting Spinel AB2O4 and Delafossite ABO2 Thin Films for “Transparent Electronics”

Reactive SputteredWide-Bandgap p-Type Semiconducting Spinel AB2O4 and Delafossite ABO2 Thin Films for “Transparent Electronics”

Correlation between the EFG Values Measured at the Cd Impurity in a Group of Cu-based Delafossites and the Semiconducting Properties of the Latter

Electronic structure of the n-type doped AgInO2 and CuAlO2 delafossites: similarities and differences

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